使用API 17TR8方法验证和验证HPHT海底连接器

B. Stewart, Sam Lee
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引用次数: 0

摘要

井口接头是海底采油树生产系统的重要组成部分。它们位于隔水管载荷路径上,这意味着除了内部压力和循环载荷外,它们还要承受高水平的弯曲和拉伸载荷。随着越来越多的油田被发现和开发,这些油田被定义为高压和/或高温(HPHT),这些载荷条件变得更加艰难。为了确保HPHT组件的完整性,API 17TR8中列出了对组件的行业要求。本技术报告提供了HPHT产品的设计验证方法和验证测试的一些要求。该方法提供了静态结构和循环能力评估的详细信息,但对如何评估井口连接器的功能和可使用性标准的详细信息较少。同样,API 17TR8不包括井口连接器的规范性验证要求,而是参考历史方法。本文描述了API 17TR8方法在20k HPHT连接器开发中的实际应用,以及如何通过全尺寸测试来验证和验证连接器设计。开发了一种满足相关行业标准要求的方法,并将其应用于连接器,以开发静态组合加载的容量图。在三维180°有限元模型上进行了验证,以确保准确捕获所有非轴对称载荷。连接器容量的定义基于API 17TR8标准,包括弹性塑性分析(即崩溃载荷、局部失效和棘轮)、通过FMECA审查定义的功能/可使用性标准,还包括API STD 17G标准,包括锁定/解锁功能、断裂失效、机械脱离、泄漏和预载荷超出等失效模式。根据API 17TR7和API STD 17G的要求,通过对正常、极限和生存能力曲线(由使用实际材料特性的“建成”有限元分析定义)的组合载荷进行全尺寸测试,验证了这些能力。记录了各种试验参数,如应变片数据、轮毂分离数据、位移等,并将其与有限元预测相关联,以证明该方法的有效性。进一步的验证是通过施加组合载荷到FEA预测的失效来确认连接器的设计裕度。测试后进行了评审,以审查API 17TR8和API STD 17G中对海底连接器验证和验证要求的适用性。结果建立在先前的测试结果的基础上,以验证API 17TR8代码用于验证和验证连接器的有效性。结果表明,连接器失效和额定负载之间的实际裕度高于API 17TR8中定义的裕度,并且表明该方法可能是保守的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
HPHT Subsea Connector Verification and Validation Using an API 17TR8 Methodology
Wellhead connectors form a critical part of subsea tree production systems. Their location in the riser load path means that they are subjected to high levels of bending and tension loading in addition to internal pressure and cyclic loading. As more fields continue to be discovered and developed that are defined as High Pressure and/or High Temperature (HPHT) these loading conditions become even more arduous. In order to ensure the integrity of HPHT components, industry requirements for components are setout in API 17TR8. This technical report provides a design verification methodology for HPHT products and some requirements for validation testing. The methodology provides detail on the assessment of static structural and cyclic capacities but less detail on how to assess the functional and serviceability criteria for wellhead connectors. Similarly, API 17TR8 does not include prescriptive validation requirements for wellhead connectors and refers back to historical methods. This paper describes a practical application of the API 17TR8 methodology to the development of a 20k HPHT connector and how it was implemented to verify and validate the connector design through full scale tests to failure. A methodology was developed to meet the requirements of the relevant industry standards and applied to the connector to develop capacity charts for static combined loading. Verification was carried out on three dimensional 180° FEA models to ensure all non axi-symmetric loading is accurately captured. Connector capacities are defined based on API 17TR8 criteria with elastic plastic analysis (i.e. collapse load, local failure and ratcheting), functionality/serviceability criteria defined through a FMECA review and also including API STD 17G criteria including failure modes such as lock/unlock functionality, fracture based failure, mechanical disengagement, leakage and preload exceedance. These capacities are validated through full scale testing based on the requirements of API 17TR7 and API STD 17G with combined loading applied to the Normal, Extreme and Survival capacity curves (as defined by "as-built" FEA using actual material properties). Various test parameters such as strain gauge data, hub separation data, displacements, etc. were recorded and correlated to FEA prediction to prove the validity of the methodology. Further validation was carried out by applying a combined load up to the FEA predicted failure to confirm the design margins of the connector. Post-test review was carried out to review the suitability of the requirements set out in API 17TR8 and API STD 17G for the verification and validation of subsea connectors. The results build on previous test results to validate the effectiveness of the API 17TR8 code for verification and validation of connectors. The results show that real margins between failure of the connector and rated loads are higher than those defined in API 17TR8 and show that the methodology can be conservative.
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